Global CO2 Capture Equipment Research Report 2025 (Status and Outlook)

 

Report Overview:

CO2 Capture Equipment refers to the technologies and systems designed to capture carbon dioxide emissions from industrial processes, power generation plants, and other anthropogenic sources, thereby reducing greenhouse gas emissions and mitigating climate change. These systems can capture CO2 directly from flue gas, process streams, or even directly from the ambient air. The captured CO2 can then be compressed, transported, stored underground (geological sequestration), or utilized in enhanced oil recovery (EOR) and various industrial applications such as chemical synthesis, beverage carbonation, or production of synthetic fuels. CO2 capture equipment plays a critical role in enabling industries to comply with environmental regulations, achieve carbon neutrality goals, and support global decarbonization initiatives.

As global climate targets become increasingly urgent and carbon pricing mechanisms expand worldwide, CO₂ capture equipment is entering a stage of large-scale deployment, driven by robust policy frameworks, innovative financing solutions, and growing industrial demand. Initially concentrated in demonstration projects and specific industries, the market is now expanding across broader industrial applications—including power generation, oil and gas, cement, and steel—under the dual influence of compliance requirements and voluntary carbon credit markets. Technological evolution, from first-generation amine absorption to advanced solvents, solid sorbents, and emerging approaches such as Direct Air Capture (DAC) and electrochemical capture, is reducing both energy intensity and unit costs, while AI-enabled material discovery and process optimization accelerate innovation cycles. Regional dynamics are also evolving, with mature markets in North America and Europe leading clustered deployments, while emerging centers in Asia-Pacific and the Middle East leverage cross-border infrastructure and hybrid carbon pricing models. As CO₂ capture capacity scales toward hundreds of millions of tons per year, equipment is transitioning from bespoke engineering solutions to more standardized, modular industrial systems, forming a market characterized by deep integration, competitive technology platforms, and rapidly expanding global demand.

By 2024, the CO₂ capture equipment market reached USD 4,067.59 million, with a projected CAGR of 16.48% between 2025 and 2035, reaching USD 16,457.01 million. Market growth is driven by structural policy support, unavoidable industrial decarbonization needs, and improving economic and technological conditions, creating a self-reinforcing growth dynamic. On a macro level, stringent climate policies—including the Paris Agreement, national decarbonization targets, carbon pricing mechanisms, and trade-related carbon regulations—have shifted carbon capture from a voluntary environmental choice to a compliance-critical and economically rational investment. Within this framework, inherent demand from hard-to-abate sectors—such as power, cement, steel, chemical, and shipping industries—serves as a second structural driver, as process emissions cannot be eliminated solely through electrification or renewable energy. Concurrently, technological advances in solvents, membranes, system integration, and digital optimization steadily enhance commercial feasibility by reducing energy consumption and operational costs, while scale effects and standardization lower capital intensity. Increased capital market participation and emerging application scenarios further reinforce these drivers, with ESG-oriented financing, long-term off-take agreements, and pre-purchased carbon credits providing revenue certainty, reducing financing barriers, and accelerating deployment.

Nevertheless, the market faces interrelated structural challenges that constrain large-scale, sustainable commercialization. Demand remains highly policy-dependent, with project initiation and equipment procurement closely tied to carbon pricing, subsidies, tax credits, and regulatory stability, leaving the market vulnerable to policy reversals and regional disparities. Core technologies are transitioning from demonstration to full commercial maturity, facing high energy and capture costs, limited long-term operational data for advanced solutions, and persistent mismatches between standardized equipment designs and the heterogeneous needs of high-emission industries. These technical uncertainties extend capital payback periods, render revenue models project-dependent, and increase financing costs, particularly for smaller suppliers. Additionally, carbon capture systems can reduce net plant efficiency and increase fuel consumption and environmental burdens unless mitigated by advanced designs, further complicating economic viability. Equipment customization, coordination gaps across the capture-transport-utilization/storage value chain, and weak cross-industry and cross-border collaboration continue to hinder integrated project development, delaying the formation of a scalable, globally interconnected market ecosystem.

Segment-wise, post-combustion capture dominates the 2024 market with a 77.8% share, reflecting its maturity and wide applicability to high-concentration point sources such as coal-fired power plants and cement factories. The fastest-growing segments are Direct Air Capture (DAC) and oxy-fuel combustion, with projected CAGRs of 20.1% and 19.2%, respectively. DAC growth is fueled by the increasing emphasis on negative emissions and supportive policies for low-concentration CO₂ capture from dispersed sources, while oxy-fuel combustion benefits from high capture efficiency and compatibility with next-generation low-emission power plants.

From an application perspective, the oil and gas industry holds the largest 2024 share at 64%, driven by high upstream and midstream emissions and early adoption of carbon management technologies in response to regulatory and ESG pressures. The fastest-growing applications are steel and metal production (CAGR 22.3%) and the chemical industry (CAGR 20.6%), reflecting intensified decarbonization efforts in traditionally hard-to-abate sectors with large process emissions and increasingly favorable policy incentives. Power generation also shows robust growth (CAGR 19.4%), supported by retrofits of aging plants and challenges in renewable energy integration, while the cement sector, despite its smaller current share, is expanding rapidly (CAGR 18.6%) due to process-related emission challenges and emerging policy support.

Geographically, North America accounted for the largest market share in 2024 at 46.9%, reflecting early deployment of CCUS projects, supportive policies such as the 45Q tax credit, and mature oil and gas infrastructure enabling large-scale adoption. Asia-Pacific is the fastest-growing region, with a projected CAGR of 24.3% from 2025 to 2035, driven by rapid industrialization, growing emissions from power, steel, and cement sectors, and increasingly favorable government incentives for decarbonization.

 

CO2 Capture Equipment Industry Chain Analysis

 

Overview of Operating CCUS Projects (Partial)

Project name	Country or Economy	Partners	Announced Capacity (Mt CO2/yr)
Alberta Carbon Trunk Line (ACTL) (ALB)	Canada	Wolf Carbon Solutions (Wolf Midstream, Enhance Energy)	14.6
Petrobras Santos Basin pre-salt oilfield CCS (ES)	Brazil	Petrobas	3 - 10.6
Century plant (TX)	USA	Mitchell group, Sandridge Energy	4.32 - 5
Labarge Shute Creek Gas Processing Plant 2010 expansion (WY)	USA	ExxonMobil, Fleur de Lis Energy LLC/Renee Acquisition LLC ; Chevron; Devon Energy Denbury	3.5
Labarge Shute Creek Gas Processing Plant original (WY)	USA	ExxonMobil, Fleur de Lis Energy LLC/Renee Acquisition LLC ; Chevron; Devon Energy Denbury	3.5
Great Plains Synfuel Plant (ND) Weyburn-Midale (SK)	USA-Canada	Dakota Gasification company, Cenovus, Whitecap, Cardinal	3
Weyburn-Midale storage	Canada	Whitecap Resources Inc., Cardinal Energy LTD.	3
Qatar LNG	Qatar	QatarEnergy LNG, ExxonMobil	1.23 - 2.1
Moomba Carbon Capture and Storage	Australia	Santos, Beach Energy	1.7
Gorgon CCS	Australia	Chevron (47.3%, operator), Shell (25%), ExxonMobil (25%), Osaka Gas (1.25%), MidOcean Energy (1 %), JERA (0.417%)	3.4 - 4
Enhance Clive Sequestration Facility (ACTL) (ALB)	Canada	Enhance Energy	1.5
Petra Nova Carbon Capture (TX)	USA	NRG (equity), JX Nippon (equity), JBIC (debt), Mizhou bank (backed by NEXI)(debt)	1.4
NWR Sturgeon Refinery (ALB)	Canada	Northwest Redwater Partnership	1.3
Quest CCS (ALB)	Canada	Canadian Natural Resources Limited, Shell Canada, Chevron Canada	1 - 1.2
Boundary Dam CCS (SASK)	Canada	Saskpower	1
Sinopec Qilu Petrochemical Shengli (Shandong)	China	Sinopec, Qilu Petrochemical	0.7 - 1
Sleipner	Norway	Equinor, Eni	1
Coffeyville fertiliser Plant (KS)	USA	Coffeyville Resources, Chaparral Energy, Coffeyville Resource Nitrogen Fertilizers	0.7 - 0.9
Lost Cabin Gas Plant (WY)	USA	Contango Oil & Gas (bought plant in 2021 from Conocophillips), ExxonMobil (formerly Denbury)	0.9
Valero Port Arthur Refinery (TX)	USA	Air products, ExxonMobil (formerly Denbury carbon solutions)	0.9
Emirates Steel Industries	UAE	ADNOC, Masdar	0.8
Uthmaniyah CO2-EOR demonstration	Saudi Arabia	Saudi Aramco	0.8
Shell Netherlands Refineries heavy residue gasification CCU	Netherlands	Shell	0.75
Snohvit CO2 capture and storage	Norway	Equinor, Petoro, TotalEnergies, Eni (following acquisition of Neptune Energy), Wintershall Dea (Harbour Energy)	0.7
Enid fertiliser (OK)	USA	Koch Nitrogen Company, Daylight Petroleum	0.68
Changling Gas plant /Jilin Oil Field CO2-EOR Full-scale (Jilin)	China	PetroChina, CNPC	0.43 - 0.6
China Energy Taizhou power (Jiangsu)	China	China Energy	0.5
Illinois Industrial Carbon Capture and Storage (IL)	USA	ADM	0.5 - 1.1
Terrell Natural Gas Processing Plant (former Val Verde) (TX)	USA	Blue Source, Occidental, Chevron	0.4 - 0.5
OCAP	Netherlands	OCAP (Linde)	0.5
Horizon mine tailings (ALB)	Canada	Canadian Natural Resources Ltd	0.4
Core Energy CO2-EOR South Chester plant (MI)	USA	Core Energy	0.35
Arkalon CO2 Compression Facility (KS)	USA	Conestoga Energy	0.19 - 0.31
CNOOC Enping offshore CCS (Hong Kong)	China	CNOOC	0.3
PCS Nitrogen-Geismar plant (LA)	USA	Nutrien, ExxonMobil (formerly Denbury carbon solutions)	0.2 - 0.3
Nutrien Redwater Fertilizer (ALB) phase 1	Canada	Nutrien (formerly Agrium)	0.3
Yulin Coal Chemical CCUS (Shaanxi) Phase 1	China	Yanchang Petroleum	0.3
Midwest AgEnergy Blue Flint ethanol (ND)	USA	Blue Flint Sequester Company LLC, Harvestone Low Carbon Partners, Ag Energy Group LLC	0.2
Sinopec Nanjing Chemical Industries CCUS Cooperation Project (Jiangsu)	China	Sinopec	0.2
Carbon Dioxide Full Oxygen Combustion Enrichment and Purification Demonstration Project Qingzhou (Shandong)	China	China United Cement Company, Tianjin Cement Industry Design & Research Institute, Shanghai Triumph Energy Conservation Engineering Co Ltd	0.2

 

Key Development Trends

Global Expansion and Diversification of Carbon Emissions Trading Systems        

Countries around the world are facing increasingly frequent and severe climate impacts. Extreme heatwaves, catastrophic flooding, and large-scale wildfires are no longer sporadic events but have become structural risks. Despite this urgency, the global economy remains off track to meet the targets of the Paris Agreement, while national interest considerations continue to dilute coordinated international action. Under the Paris framework, Parties are expected to submit updated Nationally Determined Contributions (NDCs) ahead of COP30. This deadline provides governments with a critical opportunity to recalibrate mitigation ambition, strengthen policy frameworks, and more deeply integrate market-based mechanisms into national climate strategies, thereby enabling higher and more credible emissions reduction pathways.

Carbon markets—particularly emissions trading systems (ETS)—have become one of the preferred climate policy instruments globally. By 2025, carbon markets are expected to cover more than 23% of global greenhouse gas emissions, roughly four times the coverage at the launch of the EU ETS in 2005. Currently, 38 carbon market systems are in operation worldwide, covering over 10 billion tonnes of CO₂-equivalent emissions, representing approximately 19% of global emissions. These systems span multiple jurisdictions, covering about one-third of the global population and 58% of global GDP. Among G20 members, 17 countries have already established or are actively developing national or subnational carbon markets, underscoring the central role of carbon pricing in major economies.

Momentum continues to build, with more than 20 countries at various stages of carbon market development. While early carbon markets were largely concentrated in advanced economies, emerging markets are now driving the next wave of implementation. Importantly, carbon market design is also evolving. Several governments—particularly in developing economies—are moving beyond traditional cap-and-trade systems toward intensity-based mechanisms. Others are adopting hybrid approaches that combine emissions trading with carbon taxes or offset mechanisms, creating more flexible and context-specific decarbonization pathways.

Advanced economies continue to refine their carbon markets. The European Union has recently completed a major reform of its ETS and plans to launch a separate market from 2027 covering buildings, road transport, and additional sectors, which is expected to roughly double emissions coverage. Canada has released draft regulations for a federal cap-and-trade system that would include upstream emissions from oil, gas, and LNG production.

At the subnational level in the United States, Oregon has relaunched its carbon market following its invalidation in 2023, while Colorado introduced its ETS in 2024, initially covering large industrial emitters and planning expansion by 2028. New York State is developing rules for an economy-wide carbon market, and Maryland is actively assessing the feasibility of a statewide system.

In parallel, emerging economies are becoming the primary engines of new carbon market deployment. In the Asia-Pacific region, India has passed legislation establishing an intensity-based carbon market for energy-intensive industries, alongside a carbon offset mechanism. China has expanded its national ETS beyond the power sector to include steel, cement, and aluminum smelting, while also evaluating a transition toward an absolute emissions cap. Indonesia’s intensity-based power-sector carbon market has been operating for two years and is set to pilot an innovative hybrid model combining caps, carbon taxes, and trading. Türkiye and Vietnam are preparing regulatory frameworks for near-term pilot launches, while Malaysia, the Philippines, and Thailand are evaluating the integration of carbon trading into national climate policies. In Latin America, Brazil has established the legal foundation for a federal carbon market and entered early implementation, while Chile is developing sectoral caps and preparing a power-sector ETS pilot.

CCUS Projects Enter a Phase of Tangible Scale-Up        

Data from the International Energy Agency (IEA) clearly indicate that global CCUS development has moved beyond the phase of isolated demonstration projects. As of April 2025, operational CCUS projects worldwide exceed 50 million tonnes per year of CO₂ capture capacity, with rapid year-on-year growth. This scale is now economically and statistically meaningful, signaling genuine industrial deployment rather than symbolic pilot activity.

In 2024, several “first-of-a-kind” projects reached major milestones. The United Kingdom approved its first natural gas power plant equipped with carbon capture, targeting annual capture of 2 million tonnes of CO₂. Sweden’s biomass CHP project became the largest carbon removal project to reach final investment decision globally. China commissioned the world’s first cement production CCUS facility based on oxy-fuel combustion. Australia launched the world’s first large-scale depleted gas field CO₂ storage project.

Beyond these flagship projects, additional breakthroughs are emerging. Indonesia’s Tangguh gas processing CCUS project reached final investment decision, while Kenya began construction of its first direct air capture (DAC) pilot following venture capital investment and carbon removal offtake agreements.

Demand signals from voluntary carbon markets are playing a decisive role in accelerating carbon removal projects. Developers of BECCS and DAC projects signed pre-purchase agreements covering nearly 6 million tonnes of CO₂ reductions in 2024, accounting for 75% of total carbon removal credit purchases that year—almost double the volume in 2023. These agreements provide revenue certainty critical to reaching FID.

More importantly, if currently planned projects are delivered on schedule, global capture capacity is projected to reach approximately 430 million tonnes per year by 2030. This implies nearly an order-of-magnitude expansion within five years—a growth trajectory typically observed only when strong policy support converges with increasingly viable commercial models.

From a CO₂ capture equipment market perspective, this shift is structurally significant. Incremental demand will no longer be driven by bespoke equipment for single landmark projects, but by parallel deployment across multiple industries and regions. This transition is pushing CO₂ capture equipment from customized engineering solutions toward standardized, replicable industrial systems.

 

Driving Factors

Strong Policy and Regulatory Push        

Policy and regulation are the most direct and decisive forces driving the development of the CO₂ capture equipment market. The global climate governance framework—most notably the Paris Agreement and the Nationally Determined Contributions (NDCs) submitted by individual countries—clearly requires deep decarbonization of industrial and energy systems by mid-century. This creates a quantified and long-term demand for decarbonization technologies, including CCS/CCUS, and provides a clear development trajectory for the equipment market.

At the national level, advanced economies have already incorporated CCS/CCUS into formal legal and regulatory frameworks. In the European Union, policies such as Fit for 55 have reshaped the EU ETS and related regulations, giving carbon capture technologies a defined role within compliance pathways. In the United States, the Section 45Q tax credit provides direct financial incentives for CCUS investments, significantly improving project economics. In emerging economies, countries such as China and Indonesia have also begun embedding CCUS targets into energy planning and industrial policy. China, in particular, is planning large-scale deployment of capture facilities in coal-based and other high-emission industries; this top-down policy approach introduces substantial incremental demand potential for equipment suppliers.

At the same time, carbon pricing mechanisms and market-based incentives provide powerful economic signals. Mature carbon markets—including the EU ETS, California’s cap-and-trade system, and the Korean ETS—cover a large share of global emissions. By assigning a price to emissions allowances, these systems effectively raise the cost of high-emission activities, improving the relative attractiveness of investing in capture equipment.

As carbon taxes and allowance prices trend upward, especially in key industrial sectors, they increasingly affect firms’ marginal cost structures. Once carbon prices exceed certain thresholds, investing in capture equipment becomes more cost-effective than purchasing emissions allowances. This logic gradually shifts carbon capture equipment from being merely a “compliance tool” to a “cost-optimization instrument.” More importantly, in voluntary carbon markets, projects such as BECCS and direct air capture (DAC) have already secured large volumes of pre-purchase agreements, providing revenue certainty that supports project financing and equipment orders. These market-based carbon credits not only enhance demand visibility but also allow equipment manufacturers to better forecast future order flows.

In fact, increasing coordination in international climate governance is shaping a converging global regulatory environment. Article 6 of the Paris Agreement establishes a mechanism for cross-border carbon credit trading, giving emissions reductions generated by CCUS projects potential international value. Meanwhile, trade policies such as the EU Carbon Border Adjustment Mechanism (CBAM) are transmitting carbon-footprint compliance pressure along global supply chains. This forces export-oriented economies and companies to seriously consider deep decarbonization solutions, including carbon capture, in order to maintain market access and competitiveness.

Overall, policy and regulation not only generate market demand but also strengthen confidence among equipment manufacturers and project investors through time-bound, wide-coverage measures. They form the foundational driver of global CO₂ capture equipment market expansion.

Irreplaceable Demand from Deep Industrial Decarbonization and Energy Security Strategies        

The fundamental demand for carbon capture equipment stems from the practical challenges faced by hard-to-abate sectors—such as power generation, steel, cement, and chemicals—in achieving deep decarbonization. Process emissions in these industries (for example, limestone calcination in cement production or chemical reduction reactions in steelmaking) cannot be fully eliminated through electrification or renewable energy substitution alone. According to the International Energy Agency’s net-zero pathway, nearly half of industrial emissions reductions by 2050 will rely on CCUS technologies. This elevates CCUS from an “optional solution” to a “necessary technology,” creating large-scale and highly certain equipment demand.

This demand is further reinforced by global energy security considerations. Amid geopolitical tensions and increased volatility during the energy transition, ensuring stable energy supply has become a top priority for many countries. For nations with abundant coal or natural gas resources—or those structurally dependent on fossil fuels—the combination of “fossil energy + CCUS” offers a pragmatic pathway to maintain energy system resilience and baseload power supply while still meeting climate objectives. As a result, national energy strategies increasingly preserve a role for fossil-based facilities equipped with carbon capture systems.

From an industrial competitiveness perspective, early deployment of carbon capture technologies is becoming a key determinant of future market positioning. As low-carbon product standards, green supply-chain requirements, and consumer preferences increasingly shift toward sustainability, companies capable of supplying “near-zero-carbon” or “low-carbon” basic materials—such as green steel or low-carbon cement—will gain first-mover advantages and pricing power. Investment in carbon capture equipment is therefore, in essence, a strategic bet on future market rules and long-term core competitiveness.

 

Global CO2 Capture Equipment Market: Market Segmentation Analysis

The research report includes specific segments by region (country), manufacturers, Type, and Application. Market segmentation creates subsets of a market based on product type, end-user or application, Geographic, and other factors. By understanding the market segments, the decision-maker can leverage this targeting in the product, sales, and marketing strategies. Market segments can power your product development cycles by informing how you create product offerings for different segments.

Key Company

Aker Solutions

Chart Industries

Everllence

GEA

Climeworks

Linde

Mitsubishi

Shell Cansolv

Air Liquide S.A

GE Vernova

Technip Energies

Saipem

Heirloom

Fujian Longking

Honeywell UOP

SPICHydropower

JGC Corporation

Bright Renewables

Babcock & Wilcox

CarbonCapture Inc.

Fluor

TONEXUS

Lanstone Group

QiYao Environmental Technology

Axens

 

Market Segmentation (by Type)

Post-Combustion

Pre-Combustion

Oxy-Fuel Combustion

Direct Air Capture (DAC)

 

Market Segmentation (by Application)

Power Generation

Oil and Gas

Cement Industry

Steel and Metal Production

Chemical Industry

Others

 

Geographic Segmentation

North America

Europe

Asia-Pacific

South America

Middle East and Africa

 

Key Benefits of This Market Research:

• Industry drivers, restraints, and opportunities covered in the study

• Neutral perspective on the market performance

• Recent industry trends and developments

• Competitive landscape & strategies of key players

• Potential & niche segments and regions exhibiting promising growth covered

• Historical, current, and projected market size, in terms of value

• In-depth analysis of the CO2 Capture Equipment Market

• Overview of the regional outlook of the CO2 Capture Equipment Market:

 

Key Reasons to Buy this Report:

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• Indicates the region and segment that is expected to witness the fastest growth as well as to dominate the market

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• Competitive landscape which incorporates the market ranking of the major players, along with new service/product launches, partnerships, business expansions, and acquisitions in the past five years of companies profiled

• Extensive company profiles comprising of company overview, company insights, product benchmarking, and SWOT analysis for the major market players

• The current as well as the future market outlook of the industry concerning recent developments which involve growth opportunities and drivers as well as challenges and restraints of both emerging as well as developed regions

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Chapter Outline

Chapter 1 mainly introduces the statistical scope of the report, market division standards, and market research methods.

 

Chapter 2 is an executive summary of different market segments (by region, product type, application, etc), including the market size of each market segment, future development potential, and so on. It offers a high-level view of the current state of the CO2 Capture Equipment Market and its likely evolution in the short to mid-term, and long term.

 

Chapter 3 makes a detailed analysis of the Market's Competitive Landscape of the market and provides the market share, capacity, output, price, latest development plan, merger, and acquisition information of the main manufacturers in the market.

 

Chapter 4 is the analysis of the whole market industrial chain, including the upstream and downstream of the industry, as well as Porter's five forces analysis.

 

Chapter 5 introduces the latest developments of the market, the driving factors and restrictive factors of the market, the challenges and risks faced by manufacturers in the industry, and the analysis of relevant policies in the industry.

 

Chapter 6 provides the analysis of various market segments according to product types, covering the market size and development potential of each market segment, to help readers find the blue ocean market in different market segments.

 

Chapter 7 provides the analysis of various market segments according to application, covering the market size and development potential of each market segment, to help readers find the blue ocean market in different downstream markets.

 

Chapter 8 provides a quantitative analysis of the market size and development potential of each region and its main countries and introduces the market development, future development prospects, market space, and capacity of each country in the world.

 

Chapter 9 details the production of products in major countries/regions and provides the production of major countries/regions.

 

Chapter 10 introduces the basic situation of the main companies in the market in detail, including product sales revenue, sales volume, price, gross profit margin, market share, product introduction, recent development, etc.

 

Chapter 11 provides a quantitative analysis of the market size and development potential of each region in the next five years.

 

Chapter 12 provides a quantitative analysis of the market size and development potential of each market segment (product type and application) in the next five years.

 

Chapter 13 is the main points and conclusions of the report.